Liquid transfer molding system for encapsulating semiconductor integrated circuits

ABSTRACT

An encapsulation system is used to encapsulate semiconductor products. A bottom mold unit includes a mold pot and a mold piston. A substrate loader loads a substrate into a cavity in the bottom mold unit. A liquid dispenser dispenses encapsulation material into the mold pot. The encapsulation material is in an uncured liquid state when placed into the mold pot. A top mold unit is clamped to the bottom mold unit.

BACKGROUND FIELD OF THE INVENTION

[0001] The present invention concerns integrated circuits and pertainsparticularly to a liquid transfer molding system for encapsulatingsemiconductor integrated circuits.

RELATED INFORMATION

[0002] After the manufacture of integrated circuits on a silicon wafersurface, the wafers are typically sawn into individual die. Each die isthen attached onto a substrate (for example a leadframe), and bondingwires are used to provide electrical connection from the die to theoutside world.

[0003] In general, transfer molding is the most widely-used method ofencapsulating semiconductor devices because of the versatility and highthroughput of such systems. The encapsulation materials used in transfermolding systems normally come in solid form. They are made bypelletizing fine powder of a mixture of resin, filler, hardener,catalyst, carbon black, etc. Some of the disadvantages of using thesepelletized mold compounds are dust (escaping from pellets), non-uniformdensity across the pellets, and moisture absorption.

[0004] Liquid encapsulating materials, on the other hand, do not havethe problems associated with pageetized powder. They do not produce dustand are very uniform in density and other properties. Most of theencapsulating materials for optoelectronics come in liquid form. Thusthey cannot be used directly in a transfer mold system. One way that iscommonly used is to turn the liquid materials into solid by partiallycuring (called B-stage) the materials to a certain degree and forming itinto pellet form. However, in this partially cured state, the materialhas a higher viscosity and thus a degraded flow behavior. In addition,the partially cured state results in poorer adhesion to substrates.

SUMMARY OF THE INVENTION

[0005] In accordance with the preferred embodiment of the presentinvention an encapsulation system is used to encapsulate semiconductorproducts. A bottom mold unit includes a mold pot and a mold piston. Asubstrate loader loads a substrate into a cavity in the bottom moldunit. A liquid dispenser dispenses encapsulation material into the moldpot. The encapsulation material is in an uncured liquid state whenplaced into the mold pot. A top mold unit is then clamped to the bottommold unit.

[0006] The present invention allows the use of liquid encapsulatingmaterials to replace the solid mold compounds in many applications. Thepresent invention also facilitates high volume production at lower costfor optoelectronic devices such as light emitting diode (LED) displaysor infrared devices.

[0007] In addition, the superior adhesion of liquid encapsulatingmaterial results in better quality products produced at lower cost thanis possible using B-stage (partially cured) materials. This is becauseadditional processes are required to produce B-stage materials,resulting in higher costs of the final product.

[0008] Further, using liquid materials opens up new applications fortransfer mold such as in the optoelectronics, where many of theoptoelectronic devices are encapsulated using cast process. In general,cast process has longer cycle time, lower throughput, and is lessautomated.

[0009] Also, using a liquid materials within a transfer mold system, itis possible to have lower molding temperature if necessary. This ispossible because of much lower viscosity of liquid materials as opposedto solid mold compounds, which take relatively more time to melt andhave higher viscosity. Besides lower viscosity, liquid encapsulatingmaterials have less air and moisture content as opposed to thepelletized mold compounds. This results in fewer air entrapment ordefect in final cured material.

[0010] Unlike standard transfer mold, which uses pelletized moldcompounds, the use of an automatic liquid dispensing system, as in thepresent invention, allows the amount of liquid material dispensed to becontrolled or adjusted with greater flexibility. This is especiallyhelpful during initial process optimization or debug. The amount ofwaste material can thus be reduced. Such adjustment is difficult, if notimpossible, with pellet mold compounds since that would mean a differentpellet size, something that the compound manufacturer would have toprovide.

BRIEF DESCRIPTION OF THE DRAWINGS

[0011]FIG. 1 is a simplified block diagram of a bottom plunger moldsystem with a liquid dispensing unit forming a liquid transfer moldsystem in accordance with a preferred embodiment of the presentinvention.

[0012]FIG. 2 is a simplified block diagram which illustrates substrateloading of the liquid transfer mold system shown in FIG. 1 in accordancewith a preferred embodiment of the present invention.

[0013]FIG. 3 is a simplified block diagram which illustrates liquidencapsulant dispensing within the liquid transfer mold system shown inFIG. 1 in accordance with a preferred embodiment of the presentinvention.

[0014]FIG. 4 is a simplified block diagram that illustrates clamping ofthe mold within the liquid transfer mold system shown in FIG. 1 inaccordance with a preferred embodiment of the present invention.

[0015]FIG. 5 is a simplified block diagram which illustrates mold cavityfilling within the liquid transfer mold system shown in FIG. 1 inaccordance with a preferred embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENT

[0016] In accordance with a preferred embodiment of the presentinvention, a liquid dispensing system is incorporated within a transfermold process in order to allow the use of liquid encapsulating materialsin place of the solid molding compounds. The resulting liquid transfermold system has the high throughput characteristic of transfer moldsystems and also the superior flow and adhesion characteristics ofliquid encapsulant systems. The present invention allows expansion ofthe use of transfer mold process within the manufacture of many othersemiconductor devices (such as optoelectronics) whose encapsulatingmaterials are currently available only in liquid form.

[0017]FIG. 1 shows a bottom plunger mold system having a top mold unit11 and a bottom mold unit 12. Mold cavities 13 are formed when top moldunit 11 is clamped to bottom mold unit 12. A mold piston/plunger(piston) 14 is used to force liquid encapsulant within a mold pot 15 upinto mold cavities 13 during the mold process. While FIG. 1 shows only asingle mold piston 14, the bottom plunger mold system may include two ormore pistons each in a separate mold pot.

[0018] Top mold unit 11 and bottom mold unit 12 are molds such as areavailable from Intercon Tools, Inc., having a business address of 280Cochrane Circle, Morgan Hill, Calif. 95037, from Diehard Engineeringhaving a business address of 7070-D Commerce Circle, Pleasanton, Calif.94588, or from another manufacturer of molds. A bottom plunger moldsystem that utilizes pelletized mold compounds may be obtained fromseveral manufactures, for example from ASM America, Inc, having abusiness address of 97 E. Brokaw Road, Suite 100, San Jose, Calif.95112-4209.

[0019] A substrate loader 16 is used to load substrates and lead framesonto bottom mold unit 12 at the location of mold cavities 13. A liquiddispensing system 17 replaces a pelletized mold compound loader found instandard transfer mold machines. Liquid dispensing system 17 includes aliquid encapsulant reservoir 19 that is filled with liquid encapsulationmolding material. For example the liquid encapsulation material is amixture of resin, filler, hardener, catalyst, carbon black, etc. Aretractable arm 20 is used to mount a dispensing head 21. Anauto-retractable pan 18 is utilized, if necessary to collect anydripping liquid from dispensing head 21. While FIG. 1 shows only asingle dispensing head 21, typically, there is a separate dispensinghead for each piston.

[0020] Liquid dispensing system 17 is, for example, a pump and valvesystem where the pump is located in liquid encapsulant reservoir 19 anda valve is located in dispensing head 21. Alternatively, liquiddispensing system 17 can be another type of liquid dispensing devicefrom the many kinds of liquid dispensing devices which are readilyavailable commercially. A refrigeration unit can be incorporated inliquid dispensing system 17 to increase the work life of liquidencapsulant, if necessary.

[0021]FIG. 2 illustrates substrate loader 16 performing substrate andlead frame loading. During substrate and lead frame loading, thesubstrate and lead frames is placed onto bottom mold unit 12 at thelocation of mold cavities 13.

[0022]FIG. 3 illustrates liquid dispensing system 17 used to dispenseliquid encapsulation material from liquid encapsulant reservoir 19.Retractable arm 20 extends placing dispensing head 21 into position todispense the liquid encapsulation material into mold pot 15.

[0023] As illustrated in FIG. 4 by arrows 41, bottom mold unit 12 isclamped to top mold unit 11.

[0024] As shown in FIG. 5, mold piston 14 is then moved upwards in orderto transfer liquid encapsulation material from mold pot 15 into cavities13. This is illustrated by an arrow 51.

[0025] Once placed into cavities 13, the liquid encapsulation materialis cured, for example, at high pressure to eliminate bubbles. Thisprocess can also be used in conjunction with vacuum to further increaseyield.

What is claimed is:
 1. An encapsulation system for encapsulatingsemiconductor products, the encapsulation system comprising: a top moldunit; a bottom mold unit, the bottom mold unit including, a mold pot,and a mold piston, a substrate loader, for loading a substrate into acavity in the bottom mold unit; and, a liquid dispenser for dispensingencapsulation material into the mold pot, the encapsulation materialbeing in an uncured liquid state when placed into the mold pot.
 2. Anencapsulation system as in claim 1, wherein the liquid dispenserincludes: a reservoir in which is stored the encapsulation material; adispensing head for dispensing the encapsulation material; and, aretractable arm for placing the dispensing head in position fordispensing the encapsulation material.
 3. An encapsulation system as inclaim 1, wherein the top mold unit includes a cavity which lines up withthe cavity in the bottom mold unit when the bottom mold unit is clampedto the top mold unit.
 4. An encapsulation system as in claim 1, whereinthe encapsulation dispensed into the mold is moved to the cavity in thebottom mold unit by extending the mold piston.
 5. An encapsulationsystem as in claim 1, wherein the encapsulation material includes resin,filler, hardener, catalyst and carbon black.
 6. A method forencapsulating semiconductor products, the method comprising thefollowing steps: (a) placing a substrate within a cavity in a bottommold unit; (b) dispensing encapsulation material into a mold pot withinthe bottom mold unit, the encapsulation material being in an uncuredliquid state when placed into the mold pot; (c) clamping the bottom moldunit to the top mold unit; and, (d) transferring the encapsulationmaterial to the cavity in the bottom mold unit.
 7. A method as in claim6, wherein step (b) includes transferring the encapsulation materialfrom a reservoir in which is stored the encapsulation material.
 8. Amethod as in claim 6, wherein step (b) includes the following substeps:(b.1) using a retractable arm to place a dispensing head over the moldpot; and, (b.2) dispensing liquid from the dispensing head into the moldpot.
 9. A method as in claim 6, wherein step (d) includes, extending amold piston located under the mold pot in order to transfer theencapsulation material to the cavity in the bottom mold unit.
 10. Amethod as in claim 6, wherein when clamping the bottom mold unit to thetop mold unit, a cavity in the top mold unit is aligned with the cavityin the bottom mold unit.